Spark Plug With Optical Sensor

ABSTRACT

A spark plug has an optical window for sensing combustion processes in an Otto engine. The optical window is located in the central electrode of the spark plug and has at least one lens exposed to the combustion chamber, as well as at least one flexible optical fiber which can conduct light through the spark plug from the lens to an analysis system.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to Swiss Application No. 166/04 filed Oct. 6, 2004 and International Application Serial No. PCT/CH2005/000580 filed Oct. 5, 2005.

TECHNICAL FIELD

The invention relates to a spark plug having an optical window for sensing combustion processes in an Otto engine wherein the optical window is located in the central electrode of the spark plug.

BACKGROUND OF THE INVENTION

To examine knocking during combustion in an Otto engine optical sensors are employed for example. They measure the brightness within the combustion chamber and thus provide a clue with respect to the time sequence of the events during combustion. For this purpose, optical sensors are for example arranged in spark plugs. However, these have a tendency to accumulate dirt after a short time for which reason optical sensors are sometimes mounted in the central electrode of sensors. During ignition the surfaces are subject to high temperatures whereby they are cleaned because the soot accumulated thereon is burned by the heat.

Spark plugs of the type mentioned in the beginning are known. DE 3001711 by Robert Bosch GmbH details various embodiments wherein for example a sapphire rod is used or a bundle of optical fibers. A disadvantage of these arrangements is that the sapphire rod has a very narrow opening angle and that in addition the optical fiber bundle cannot be assigned to the exact positions.

It has to be pointed out that for the examining of knocking a large surface area around the spark plug must be analyzed.

BRIEF SUMMARY OF OBJECT OF THE INVENTION

It is an object of the present invention to provide a spark plug having an optical sensor which can sense the light emission over a large area around the spark plug and optionally enables direction-dependent analysis.

This object has been achieved by the fact that the optical window has at least one lens exposed to the combustion chamber as well as at least one flexible optical fiber which can conduct light from the lens through the spark plug to an analysis system.

SHORT DESCRIPTION OF THE DRAWINGS

In the following the invention will be explained in more detail with respect to the drawings. The Figures show

FIG. 1 a schematic representation of a tip of a spark plug according to the invention;

FIG. 2 an alternative embodiment of a schematic representation of a tip of a spark plug according to the invention.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

Similar designations in the Figures refer to the same explanations.

FIG. 1 shows a schematic representation of a tip of a spark plug 1 according to the invention. The latter comprises a central electrode 2 and a measuring electrode 3, these two electrodes being separated from each other by an insulator 4. During an ignition event a spark strikes between the two electrodes. In the examples shown herein air-surface gap spark plugs are shown which have the advantage that the view of the optical window is less impaired. Other spark plugs, however, can be used as well.

The advantage is, however, that series spark plugs can be used since these are much more cost-effective in preparation than special purpose fabrications.

The central electrode 2 has the shape of a tube and therefore has an inner opening. This opening has, at its end facing the combustion chamber 10, a lens 5.

The axis of the lens 5 always extends in the direction of the spark plug axis.

In FIG. 1 the lens 5 is embodied in a way that light L incoming perpendicularly with respect to the lens axis is deflected by 90° into the lens 5. The light beam exiting from the lens 5 is conducted into one of the plurality of flexible optical fibers 6 which are arranged adjacent to the lens 5 at the inner surface thereof on a circle. Thus, the light intensity can be evaluated in a site-dependent manner since adjoining optical fibers receive light from other sectors.

A preferred embodiment of the lens 5 is shown in FIG. 1. This lens has an essentially cylindrical shape wherein the edge facing the combustion chamber 10 has a refractive phase 7. At this refractive phase 7 light L impinging on the lens 5 from a direction perpendicular to the axis A is deflected to an opposed indentation 8. This indentation 8 extends in an annular shape on the lateral surface area of the cylinder. Its phase 9 opposite to the combustion chamber 10 is metallized. The light beam impinging onto this metallized phase 9 is deflected in the desired direction and finally enters the optical fiber 6. The mirror is achieved by coating the phase with platinum or gold for example. Since this layer is not directly exposed to the combustion chamber 10 there is no risk of damage due to the combustion in the engine.

In addition, another optical fiber 6′ can be arranged adjacent to the lens centrally at the inner surface thereof. Advantageously, the inner surface of the lens 5 is embodied with a concave shape.

FIG. 2 shows a double lens system having the lenses 5′ and 5″.

This double lens system consists of at least one essentially piano-concave lens 5″ and a double-concave lens 5′ wherein the planar face of the plano-concave lens 5″ is exposed to the combustion chamber. The central optical fiber 6′ is directly contiguous with the double-concave lens 5′. The lenses can be embodied in a way that a coverage angle of the double lens system 5′, 5″ is at least 120°, preferably at least 135°, in particular up to 140°.

This arrangement allows also a detection of light beams L coming from the lateral region of the spark plug.

Preferably, the lenses are manufactured from sapphire or quartz glass.

The lenses as well as the optical fibers are surrounded by a sheath having the function of the central electrode 2. This sheath preferably is made of platinum or gold or an alloy thereof.

Generally, the optical sensor including the lenses and the optical fibers has a diameter of less than 2 mm, mostly between 1.5 and 1.8 mm. The central cavity of the central electrode 2 therefore must have these dimensions.

It is important for the application range that the spark plug can withstand a permanent temperature load of 600° C. and a temporary temperature load of 900° C.

The advantage of this invention is that with this spark plug a measuring system can be provided which on the one hand does not accumulate dirt due to the arrangement of the optical windows in the central electrode 2 while on the other hand measurement data can be acquired separately in distinct regions in a targeted manner which can also be evaluated separately.

In addition, by means of an optical fiber which is arranged centrally light from the whole combustion chamber can be detected. 

1. A spark plug having an optical window for sensing combustion processes in an Otto engine wherein the optical window is located in the central electrode of the spark plug and wherein the optical window has at least one lens exposed to the combustion chamber as well as at least one flexible optical fiber which can conduct light from the lens through the spark plug to an analysis system.
 2. A spark plug according to claim 1 wherein the spark plug is an air-surface gap spark plug.
 3. A spark plug according to claim 1 wherein the spark plug is a series spark plug.
 4. A spark plug according to claim 1 wherein the axis of the lens extends in the direction of the spark plug axis and is adapted to deflect light impinging perpendicularly to the lens axis by 90° into the lens.
 5. A spark plug according to claim 4 wherein adjacent to the lens at the inner surface thereof there is arranged a plurality of optical fibers on a circle.
 6. A spark plug according to claim 4 wherein the lens essentially has a cylindrical shape wherein the edge facing the combustion chamber has a refractive phase and the lateral surface area of the cylinder has an annular indentation the phase of which opposite to the combustion chamber is metallized.
 7. A spark plug according to claim 4 wherein adjacent to the lens at the inner surface thereof an optical fiber is centrally arranged.
 8. A spark plug according to claim 7 wherein the inner surface of the lens is embodied with a concave shape.
 9. A spark plug according to claim 1 wherein the optical window comprises a double lens system.
 10. A spark plug according to claim 9 wherein the double lens system consists of at least one essentially plano-concave lens and a double-concave lens wherein the planar surface of the piano-concave lens is exposed to the combustion chamber.
 11. A spark plug according to claim 9 wherein the coverage angle of the double lens system is at least 120°.
 12. A spark plug according to claim 4 wherein that at least one lens is made from one of sapphire and quartz glass.
 13. A spark plug according to claim 1 wherein the optical window is surrounded by a sheath functioning as the central electrode.
 14. A spark plug according to claim 13 wherein the sheath is essentially made of one of platinum, gold and an alloy thereof.
 15. A spark plug according to claim 1 wherein the spark plug can withstand a permanent temperature load of 600° C. and a temporary temperature load of 900° C.
 16. A spark plug according to claim 9 wherein the coverage angle of the double lens system is at least 135°.
 17. A spark plug according to claim 9 wherein the coverage angle of the double lens system is at least 140°. 